Complex matrix inversion is a very computationally demanding operation in advanced multiantenna wireless communications. Traditionally, systolic array-based QR decomposition (QRD) is used to invert large matrices. However, the matrices involved in MIMO baseband processing in mobile handsets are generally small which means QRD is not necessarily efficient. In this paper, a new method is proposed using programmable hardware units which not only achieves higher performance but also consumes less silicon area. Furthermore, the hardware can be reused for many other operations such as complex matrix multiplication, filtering, correlation and FFT/IFFT.
Abstract − This paper presents a novel hardware interleaver architecture for unified parallel turbo decoding. The architecture is fully re-configurable among multiple standards like HSPA Evolution, DVB-SH, 3GPP-LTE and WiMAX. Turbo codes being widely used for error correction in today's consumer electronics are prone to introduce higher latency due to bigger block sizes and multiple iterations. Many parallel turbo decoding architectures have recently been proposed to enhance the channel throughput but the interleaving algorithms used in different standards do not freely allow using them due to higher percentage of memory conflicts. The architecture presented in this paper provides a re-configurable platform for implementing the parallel interleavers for different standards by managing the conflicts involved in each. The memory conflicts are managed by applying different approaches like stream misalignment, memory division and use of small FIFO buffer. The proposed flexible architecture is low cost and consumes 0.085 mm 2 area in 65nm CMOS process. It can implement up to 8 parallel interleavers and can operate at a frequency of 200 MHz, thus providing significant support to higher throughput systems based on parallel SISO processors.
This paper presents a programmable MMSE soft-output MIMO symbol detector that supports 600 Mbps data rate defined in 802.11n. The detector is implemented using a multi-core floating-point processor and configurable soft-bit demapper. Owing to the dynamic range supplied by the floating-point SIMD datapath, special algorithms can be adopted to reduce the computational latency of channel processing with sufficient numerical stability for large channel matrices. When compared to several existing fixed-functional solutions, the detector proposed in this paper is smaller and faster. More important, it is programmable and configurable so that it can support various MIMO transmission schemes defined by different standards.
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